/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package org.apache.lucene.util.automaton;

import java.util.Arrays;
import java.util.BitSet;
import java.util.Objects;
import org.apache.lucene.internal.hppc.IntHashSet;
import org.apache.lucene.util.Accountable;
import org.apache.lucene.util.ArrayUtil;
import org.apache.lucene.util.InPlaceMergeSorter;
import org.apache.lucene.util.RamUsageEstimator;
import org.apache.lucene.util.Sorter;

// TODO
//   - could use packed int arrays instead
//   - could encode dest w/ delta from to?

/**
 * Represents an automaton and all its states and transitions. States are integers and must be
 * created using {@link #createState}. Mark a state as an accept state using {@link #setAccept}. Add
 * transitions using {@link #addTransition}. Each state must have all of its transitions added at
 * once; if this is too restrictive then use {@link Automaton.Builder} instead. State 0 is always
 * the initial state. Once a state is finished, either because you've starting adding transitions to
 * another state or you call {@link #finishState}, then that states transitions are sorted (first by
 * min, then max, then dest) and reduced (transitions with adjacent labels going to the same dest
 * are combined).
 *
 * @lucene.experimental
 */
public class Automaton implements Accountable, TransitionAccessor {

  /**
   * Where we next write to the int[] states; this increments by 2 for each added state because we
   * pack a pointer to the transitions array and a count of how many transitions leave the state.
   */
  private int nextState;

  /**
   * Where we next write to in int[] transitions; this increments by 3 for each added transition
   * because we pack min, max, dest in sequence.
   */
  private int nextTransition;

  /**
   * Current state we are adding transitions to; the caller must add all transitions for this state
   * before moving onto another state.
   */
  private int curState = -1;

  /**
   * Index in the transitions array, where this states leaving transitions are stored, or -1 if this
   * state has not added any transitions yet, followed by number of transitions.
   */
  private int[] states;

  private final BitSet isAccept;

  /** Holds toState, min, max for each transition. */
  private int[] transitions;

  /** True if no state has two transitions leaving with the same label. */
  private boolean deterministic = true;

  /** Sole constructor; creates an automaton with no states. */
  public Automaton() {
    this(2, 2);
  }

  /**
   * Constructor which creates an automaton with enough space for the given number of states and
   * transitions.
   *
   * @param numStates Number of states.
   * @param numTransitions Number of transitions.
   */
  public Automaton(int numStates, int numTransitions) {
    states = new int[numStates * 2];
    isAccept = new BitSet(numStates);
    transitions = new int[numTransitions * 3];
  }

  /** Create a new state. */
  public int createState() {
    growStates();
    int state = nextState / 2;
    states[nextState] = -1;
    nextState += 2;
    return state;
  }

  /** Set or clear this state as an accept state. */
  public void setAccept(int state, boolean accept) {
    Objects.checkIndex(state, getNumStates());
    isAccept.set(state, accept);
  }

  /**
   * Sugar to get all transitions for all states. This is object-heavy; it's better to iterate state
   * by state instead.
   */
  public Transition[][] getSortedTransitions() {
    int numStates = getNumStates();
    Transition[][] transitions = new Transition[numStates][];
    for (int s = 0; s < numStates; s++) {
      int numTransitions = getNumTransitions(s);
      transitions[s] = new Transition[numTransitions];
      for (int t = 0; t < numTransitions; t++) {
        Transition transition = new Transition();
        getTransition(s, t, transition);
        transitions[s][t] = transition;
      }
    }

    return transitions;
  }

  /**
   * Returns accept states. If the bit is set then that state is an accept state.
   *
   * <p>expert: Use {@link #isAccept(int)} instead, unless you really need to scan bits.
   *
   * @lucene.internal This method signature may change in the future
   */
  public BitSet getAcceptStates() {
    return isAccept;
  }

  /** Returns true if this state is an accept state. */
  public boolean isAccept(int state) {
    return isAccept.get(state);
  }

  /** Add a new transition with min = max = label. */
  public void addTransition(int source, int dest, int label) {
    addTransition(source, dest, label, label);
  }

  /** Add a new transition with the specified source, dest, min, max. */
  public void addTransition(int source, int dest, int min, int max) {
    assert nextTransition % 3 == 0;

    int bounds = nextState / 2;
    Objects.checkIndex(source, bounds);
    Objects.checkIndex(dest, bounds);

    growTransitions();
    if (curState != source) {
      if (curState != -1) {
        finishCurrentState();
      }

      // Move to next source:
      curState = source;
      if (states[2 * curState] != -1) {
        throw new IllegalStateException(
            "from state (" + source + ") already had transitions added");
      }
      assert states[2 * curState + 1] == 0;
      states[2 * curState] = nextTransition;
    }

    transitions[nextTransition++] = dest;
    transitions[nextTransition++] = min;
    transitions[nextTransition++] = max;

    // Increment transition count for this state
    states[2 * curState + 1]++;
  }

  /**
   * Add a [virtual] epsilon transition between source and dest. Dest state must already have all
   * transitions added because this method simply copies those same transitions over to source.
   */
  public void addEpsilon(int source, int dest) {
    Transition t = new Transition();
    int count = initTransition(dest, t);
    for (int i = 0; i < count; i++) {
      getNextTransition(t);
      addTransition(source, t.dest, t.min, t.max);
    }
    if (isAccept(dest)) {
      setAccept(source, true);
    }
  }

  /**
   * Copies over all states/transitions from other. The states numbers are sequentially assigned
   * (appended).
   */
  public void copy(Automaton other) {

    // Bulk copy and then fixup the state pointers:
    int stateOffset = getNumStates();
    states = ArrayUtil.grow(states, nextState + other.nextState);
    System.arraycopy(other.states, 0, states, nextState, other.nextState);
    for (int i = 0; i < other.nextState; i += 2) {
      if (states[nextState + i] != -1) {
        states[nextState + i] += nextTransition;
      }
    }
    nextState += other.nextState;
    int otherNumStates = other.getNumStates();
    BitSet otherAcceptStates = other.getAcceptStates();
    int state = 0;
    while (state < otherNumStates && (state = otherAcceptStates.nextSetBit(state)) != -1) {
      setAccept(stateOffset + state, true);
      state++;
    }

    // Bulk copy and then fixup dest for each transition:
    transitions = ArrayUtil.grow(transitions, nextTransition + other.nextTransition);
    System.arraycopy(other.transitions, 0, transitions, nextTransition, other.nextTransition);
    for (int i = 0; i < other.nextTransition; i += 3) {
      transitions[nextTransition + i] += stateOffset;
    }
    nextTransition += other.nextTransition;

    if (other.deterministic == false) {
      deterministic = false;
    }
  }

  /** Freezes the last state, sorting and reducing the transitions. */
  private void finishCurrentState() {
    int numTransitions = states[2 * curState + 1];
    assert numTransitions > 0;

    int offset = states[2 * curState];
    int start = offset / 3;
    destMinMaxSorter.sort(start, start + numTransitions);

    // Reduce any "adjacent" transitions:
    int upto = 0;
    int min = -1;
    int max = -1;
    int dest = -1;

    for (int i = 0; i < numTransitions; i++) {
      int tDest = transitions[offset + 3 * i];
      int tMin = transitions[offset + 3 * i + 1];
      int tMax = transitions[offset + 3 * i + 2];

      if (dest == tDest) {
        if (tMin <= max + 1) {
          if (tMax > max) {
            max = tMax;
          }
        } else {
          if (dest != -1) {
            transitions[offset + 3 * upto] = dest;
            transitions[offset + 3 * upto + 1] = min;
            transitions[offset + 3 * upto + 2] = max;
            upto++;
          }
          min = tMin;
          max = tMax;
        }
      } else {
        if (dest != -1) {
          transitions[offset + 3 * upto] = dest;
          transitions[offset + 3 * upto + 1] = min;
          transitions[offset + 3 * upto + 2] = max;
          upto++;
        }
        dest = tDest;
        min = tMin;
        max = tMax;
      }
    }

    if (dest != -1) {
      // Last transition
      transitions[offset + 3 * upto] = dest;
      transitions[offset + 3 * upto + 1] = min;
      transitions[offset + 3 * upto + 2] = max;
      upto++;
    }

    nextTransition -= (numTransitions - upto) * 3;
    states[2 * curState + 1] = upto;

    // Sort transitions by min/max/dest:
    minMaxDestSorter.sort(start, start + upto);

    if (deterministic && upto > 1) {
      int lastMax = transitions[offset + 2];
      for (int i = 1; i < upto; i++) {
        min = transitions[offset + 3 * i + 1];
        if (min <= lastMax) {
          deterministic = false;
          break;
        }
        lastMax = transitions[offset + 3 * i + 2];
      }
    }
  }

  /**
   * Returns true if this automaton is deterministic (for ever state there is only one transition
   * for each label).
   */
  public boolean isDeterministic() {
    return deterministic;
  }

  /**
   * Finishes the current state; call this once you are done adding transitions for a state. This is
   * automatically called if you start adding transitions to a new source state, but for the last
   * state you add you need to this method yourself.
   */
  public void finishState() {
    if (curState != -1) {
      finishCurrentState();
      curState = -1;
    }
  }

  // TODO: add finish() to shrink wrap the arrays?

  /** How many states this automaton has. */
  public int getNumStates() {
    return nextState / 2;
  }

  /** How many transitions this automaton has. */
  public int getNumTransitions() {
    return nextTransition / 3;
  }

  @Override
  public int getNumTransitions(int state) {
    assert state >= 0;
    assert state < getNumStates();
    int count = states[2 * state + 1];
    if (count == -1) {
      return 0;
    } else {
      return count;
    }
  }

  private void growStates() {
    if (nextState + 2 > states.length) {
      states = ArrayUtil.grow(states, nextState + 2);
    }
  }

  private void growTransitions() {
    if (nextTransition + 3 > transitions.length) {
      transitions = ArrayUtil.grow(transitions, nextTransition + 3);
    }
  }

  /** Sorts transitions by dest, ascending, then min label ascending, then max label ascending */
  private final Sorter destMinMaxSorter =
      new InPlaceMergeSorter() {

        private void swapOne(int i, int j) {
          int x = transitions[i];
          transitions[i] = transitions[j];
          transitions[j] = x;
        }

        @Override
        protected void swap(int i, int j) {
          int iStart = 3 * i;
          int jStart = 3 * j;
          swapOne(iStart, jStart);
          swapOne(iStart + 1, jStart + 1);
          swapOne(iStart + 2, jStart + 2);
        }

        @Override
        protected int compare(int i, int j) {
          int iStart = 3 * i;
          int jStart = 3 * j;

          // First dest:
          int iDest = transitions[iStart];
          int jDest = transitions[jStart];
          if (iDest < jDest) {
            return -1;
          } else if (iDest > jDest) {
            return 1;
          }

          // Then min:
          int iMin = transitions[iStart + 1];
          int jMin = transitions[jStart + 1];
          if (iMin < jMin) {
            return -1;
          } else if (iMin > jMin) {
            return 1;
          }

          // Then max:
          int iMax = transitions[iStart + 2];
          int jMax = transitions[jStart + 2];
          if (iMax < jMax) {
            return -1;
          } else if (iMax > jMax) {
            return 1;
          }

          return 0;
        }
      };

  /** Sorts transitions by min label, ascending, then max label ascending, then dest ascending */
  private final Sorter minMaxDestSorter =
      new InPlaceMergeSorter() {

        private void swapOne(int i, int j) {
          int x = transitions[i];
          transitions[i] = transitions[j];
          transitions[j] = x;
        }

        @Override
        protected void swap(int i, int j) {
          int iStart = 3 * i;
          int jStart = 3 * j;
          swapOne(iStart, jStart);
          swapOne(iStart + 1, jStart + 1);
          swapOne(iStart + 2, jStart + 2);
        }

        @Override
        protected int compare(int i, int j) {
          int iStart = 3 * i;
          int jStart = 3 * j;

          // First min:
          int iMin = transitions[iStart + 1];
          int jMin = transitions[jStart + 1];
          if (iMin < jMin) {
            return -1;
          } else if (iMin > jMin) {
            return 1;
          }

          // Then max:
          int iMax = transitions[iStart + 2];
          int jMax = transitions[jStart + 2];
          if (iMax < jMax) {
            return -1;
          } else if (iMax > jMax) {
            return 1;
          }

          // Then dest:
          int iDest = transitions[iStart];
          int jDest = transitions[jStart];
          if (iDest < jDest) {
            return -1;
          } else if (iDest > jDest) {
            return 1;
          }

          return 0;
        }
      };

  @Override
  public int initTransition(int state, Transition t) {
    assert state < nextState / 2 : "state=" + state + " nextState=" + nextState;
    t.source = state;
    t.transitionUpto = states[2 * state];
    return getNumTransitions(state);
  }

  @Override
  public void getNextTransition(Transition t) {
    // Make sure there is still a transition left:
    assert (t.transitionUpto + 3 - states[2 * t.source]) <= 3 * states[2 * t.source + 1];

    // Make sure transitions are in fact sorted:
    assert transitionSorted(t);

    t.dest = transitions[t.transitionUpto++];
    t.min = transitions[t.transitionUpto++];
    t.max = transitions[t.transitionUpto++];
  }

  private boolean transitionSorted(Transition t) {

    int upto = t.transitionUpto;
    if (upto == states[2 * t.source]) {
      // Transition isn't initialized yet (this is the first transition); don't check:
      return true;
    }

    int nextDest = transitions[upto];
    int nextMin = transitions[upto + 1];
    int nextMax = transitions[upto + 2];
    if (nextMin > t.min) {
      return true;
    } else if (nextMin < t.min) {
      return false;
    }

    // Min is equal, now test max:
    if (nextMax > t.max) {
      return true;
    } else if (nextMax < t.max) {
      return false;
    }

    // Max is also equal, now test dest:
    if (nextDest > t.dest) {
      return true;
    } else if (nextDest < t.dest) {
      return false;
    }

    // We should never see fully equal transitions here:
    return false;
  }

  @Override
  public void getTransition(int state, int index, Transition t) {
    int i = states[2 * state] + 3 * index;
    t.source = state;
    t.dest = transitions[i++];
    t.min = transitions[i++];
    t.max = transitions[i++];
  }

  static void appendCharString(int c, StringBuilder b) {
    if (c >= 0x21 && c <= 0x7e && c != '\\' && c != '"') b.appendCodePoint(c);
    else {
      b.append("\\\\U");
      String s = Integer.toHexString(c);
      if (c < 0x10) b.append("0000000").append(s);
      else if (c < 0x100) b.append("000000").append(s);
      else if (c < 0x1000) b.append("00000").append(s);
      else if (c < 0x10000) b.append("0000").append(s);
      else if (c < 0x100000) b.append("000").append(s);
      else if (c < 0x1000000) b.append("00").append(s);
      else if (c < 0x10000000) b.append("0").append(s);
      else b.append(s);
    }
  }

  /*
  public void writeDot(String fileName) {
    if (fileName.indexOf('/') == -1) {
      fileName = "/l/la/lucene/core/" + fileName + ".dot";
    }
    try {
      PrintWriter pw = new PrintWriter(fileName);
      pw.println(toDot());
      pw.close();
    } catch (IOException ioe) {
      throw new RuntimeException(ioe);
    }
  }
  */

  /**
   * Returns the dot (graphviz) representation of this automaton. This is extremely useful for
   * visualizing the automaton.
   */
  public String toDot() {
    StringBuilder b = new StringBuilder();
    b.append("digraph Automaton {\n");
    b.append("  rankdir = LR\n");
    b.append("  node [width=0.2, height=0.2, fontsize=8]\n");
    final int numStates = getNumStates();
    if (numStates > 0) {
      b.append("  initial [shape=plaintext,label=\"\"]\n");
      b.append("  initial -> 0\n");
    }

    Transition t = new Transition();

    for (int state = 0; state < numStates; state++) {
      b.append("  ");
      b.append(state);
      if (isAccept(state)) {
        b.append(" [shape=doublecircle,label=\"").append(state).append("\"]\n");
      } else {
        b.append(" [shape=circle,label=\"").append(state).append("\"]\n");
      }
      int numTransitions = initTransition(state, t);
      // System.out.println("toDot: state " + state + " has " + numTransitions + " transitions;
      // t.nextTrans=" + t.transitionUpto);
      for (int i = 0; i < numTransitions; i++) {
        getNextTransition(t);
        // System.out.println("  t.nextTrans=" + t.transitionUpto + " t=" + t);
        assert t.max >= t.min;
        b.append("  ");
        b.append(state);
        b.append(" -> ");
        b.append(t.dest);
        b.append(" [label=\"");
        appendCharString(t.min, b);
        if (t.max != t.min) {
          b.append('-');
          appendCharString(t.max, b);
        }
        b.append("\"]\n");
        // System.out.println("  t=" + t);
      }
    }
    b.append('}');
    return b.toString();
  }

  /** Returns sorted array of all interval start points. */
  public int[] getStartPoints() {
    IntHashSet pointset = new IntHashSet();
    pointset.add(Character.MIN_CODE_POINT);
    // System.out.println("getStartPoints");
    for (int s = 0; s < nextState; s += 2) {
      int trans = states[s];
      int limit = trans + 3 * states[s + 1];
      // System.out.println("  state=" + (s/2) + " trans=" + trans + " limit=" + limit);
      while (trans < limit) {
        int min = transitions[trans + 1];
        int max = transitions[trans + 2];
        // System.out.println("    min=" + min);
        pointset.add(min);
        if (max < Character.MAX_CODE_POINT) {
          pointset.add(max + 1);
        }
        trans += 3;
      }
    }
    int[] points = pointset.toArray();
    Arrays.sort(points);
    return points;
  }

  /**
   * Performs lookup in transitions, assuming determinism.
   *
   * @param state starting state
   * @param label codepoint to look up
   * @return destination state, -1 if no matching outgoing transition
   */
  public int step(int state, int label) {
    return next(state, 0, label, null);
  }

  /**
   * Looks for the next transition that matches the provided label, assuming determinism.
   *
   * <p>This method is similar to {@link #step(int, int)} but is used more efficiently when
   * iterating over multiple transitions from the same source state. It keeps the latest reached
   * transition index in {@code transition.transitionUpto} so the next call to this method can
   * continue from there instead of restarting from the first transition.
   *
   * @param transition The transition to start the lookup from (inclusive, using its {@link
   *     Transition#source} and {@link Transition#transitionUpto}). It is updated with the matched
   *     transition; or with {@link Transition#dest} = -1 if no match.
   * @param label The codepoint to look up.
   * @return The destination state; or -1 if no matching outgoing transition.
   */
  public int next(Transition transition, int label) {
    return next(transition.source, transition.transitionUpto, label, transition);
  }

  /**
   * Looks for the next transition that matches the provided label, assuming determinism.
   *
   * @param state The source state.
   * @param fromTransitionIndex The transition index to start the lookup from (inclusive); negative
   *     interpreted as 0.
   * @param label The codepoint to look up.
   * @param transition The output transition to update with the matching transition; or null for no
   *     update.
   * @return The destination state; or -1 if no matching outgoing transition.
   */
  private int next(int state, int fromTransitionIndex, int label, Transition transition) {
    assert state >= 0;
    assert label >= 0;
    int stateIndex = 2 * state;
    int firstTransitionIndex = states[stateIndex];
    int numTransitions = states[stateIndex + 1];

    // Since transitions are sorted,
    // binary search the transition for which label is within [minLabel, maxLabel].
    int low = Math.max(fromTransitionIndex, 0);
    int high = numTransitions - 1;
    while (low <= high) {
      int mid = (low + high) >>> 1;
      int transitionIndex = firstTransitionIndex + 3 * mid;
      int minLabel = transitions[transitionIndex + 1];
      if (minLabel > label) {
        high = mid - 1;
      } else {
        int maxLabel = transitions[transitionIndex + 2];
        if (maxLabel < label) {
          low = mid + 1;
        } else {
          int destState = transitions[transitionIndex];
          if (transition != null) {
            transition.dest = destState;
            transition.min = minLabel;
            transition.max = maxLabel;
            transition.transitionUpto = mid;
          }
          return destState;
        }
      }
    }
    int destState = -1;
    if (transition != null) {
      transition.dest = destState;
      transition.transitionUpto = low;
    }
    return destState;
  }

  /**
   * Records new states and transitions and then {@link #finish} creates the {@link Automaton}. Use
   * this when you cannot create the Automaton directly because it's too restrictive to have to add
   * all transitions leaving each state at once.
   */
  public static class Builder {
    private int nextState = 0;
    private final BitSet isAccept;
    private int[] transitions;
    private int nextTransition = 0;

    /** Default constructor, pre-allocating for 16 states and transitions. */
    public Builder() {
      this(16, 16);
    }

    /**
     * Constructor which creates a builder with enough space for the given number of states and
     * transitions.
     *
     * @param numStates Number of states.
     * @param numTransitions Number of transitions.
     */
    public Builder(int numStates, int numTransitions) {
      isAccept = new BitSet(numStates);
      transitions = new int[numTransitions * 4];
    }

    /** Add a new transition with min = max = label. */
    public void addTransition(int source, int dest, int label) {
      addTransition(source, dest, label, label);
    }

    /** Add a new transition with the specified source, dest, min, max. */
    public void addTransition(int source, int dest, int min, int max) {
      if (transitions.length < nextTransition + 4) {
        transitions = ArrayUtil.grow(transitions, nextTransition + 4);
      }
      transitions[nextTransition++] = source;
      transitions[nextTransition++] = dest;
      transitions[nextTransition++] = min;
      transitions[nextTransition++] = max;
    }

    /**
     * Add a [virtual] epsilon transition between source and dest. Dest state must already have all
     * transitions added because this method simply copies those same transitions over to source.
     */
    public void addEpsilon(int source, int dest) {
      for (int upto = 0; upto < nextTransition; upto += 4) {
        if (transitions[upto] == dest) {
          addTransition(
              source, transitions[upto + 1], transitions[upto + 2], transitions[upto + 3]);
        }
      }
      if (isAccept(dest)) {
        setAccept(source, true);
      }
    }

    /**
     * Sorts transitions first then min label ascending, then max label ascending, then dest
     * ascending
     */
    private final Sorter sorter =
        new InPlaceMergeSorter() {

          private void swapOne(int i, int j) {
            int x = transitions[i];
            transitions[i] = transitions[j];
            transitions[j] = x;
          }

          @Override
          protected void swap(int i, int j) {
            int iStart = 4 * i;
            int jStart = 4 * j;
            swapOne(iStart, jStart);
            swapOne(iStart + 1, jStart + 1);
            swapOne(iStart + 2, jStart + 2);
            swapOne(iStart + 3, jStart + 3);
          }

          @Override
          protected int compare(int i, int j) {
            int iStart = 4 * i;
            int jStart = 4 * j;

            // First src:
            int iSrc = transitions[iStart];
            int jSrc = transitions[jStart];
            if (iSrc < jSrc) {
              return -1;
            } else if (iSrc > jSrc) {
              return 1;
            }

            // Then min:
            int iMin = transitions[iStart + 2];
            int jMin = transitions[jStart + 2];
            if (iMin < jMin) {
              return -1;
            } else if (iMin > jMin) {
              return 1;
            }

            // Then max:
            int iMax = transitions[iStart + 3];
            int jMax = transitions[jStart + 3];
            if (iMax < jMax) {
              return -1;
            } else if (iMax > jMax) {
              return 1;
            }

            // First dest:
            int iDest = transitions[iStart + 1];
            int jDest = transitions[jStart + 1];
            if (iDest < jDest) {
              return -1;
            } else if (iDest > jDest) {
              return 1;
            }

            return 0;
          }
        };

    /** Compiles all added states and transitions into a new {@code Automaton} and returns it. */
    public Automaton finish() {
      // Create automaton with the correct size.
      int numStates = nextState;
      int numTransitions = nextTransition / 4;
      Automaton a = new Automaton(numStates, numTransitions);

      // Create all states.
      for (int state = 0; state < numStates; state++) {
        a.createState();
        a.setAccept(state, isAccept(state));
      }

      // Create all transitions
      sorter.sort(0, numTransitions);
      for (int upto = 0; upto < nextTransition; upto += 4) {
        a.addTransition(
            transitions[upto], transitions[upto + 1], transitions[upto + 2], transitions[upto + 3]);
      }

      a.finishState();

      return a;
    }

    /** Create a new state. */
    public int createState() {
      return nextState++;
    }

    /** Set or clear this state as an accept state. */
    public void setAccept(int state, boolean accept) {
      Objects.checkIndex(state, getNumStates());
      this.isAccept.set(state, accept);
    }

    /** Returns true if this state is an accept state. */
    public boolean isAccept(int state) {
      return this.isAccept.get(state);
    }

    /** How many states this automaton has. */
    public int getNumStates() {
      return nextState;
    }

    /** Copies over all states/transitions from other. */
    public void copy(Automaton other) {
      int offset = getNumStates();
      int otherNumStates = other.getNumStates();

      // Copy all states
      copyStates(other);

      // Copy all transitions
      Transition t = new Transition();
      for (int s = 0; s < otherNumStates; s++) {
        int count = other.initTransition(s, t);
        for (int i = 0; i < count; i++) {
          other.getNextTransition(t);
          addTransition(offset + s, offset + t.dest, t.min, t.max);
        }
      }
    }

    /** Copies over all states from other. */
    public void copyStates(Automaton other) {
      int otherNumStates = other.getNumStates();
      for (int s = 0; s < otherNumStates; s++) {
        int newState = createState();
        setAccept(newState, other.isAccept(s));
      }
    }
  }

  @Override
  public long ramBytesUsed() {
    // TODO: BitSet RAM usage (isAccept.size()/8) isn't fully accurate...
    return RamUsageEstimator.NUM_BYTES_OBJECT_HEADER
        + RamUsageEstimator.sizeOf(states)
        + RamUsageEstimator.sizeOf(transitions)
        + RamUsageEstimator.NUM_BYTES_OBJECT_HEADER
        + (isAccept.size() / 8)
        + RamUsageEstimator.NUM_BYTES_OBJECT_REF
        + 2L * RamUsageEstimator.NUM_BYTES_OBJECT_REF
        + 3 * Integer.BYTES
        + 1;
  }
}
